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Preprint UCRL-JC-147325
A Whole Body Counting Facility in a Remote Enewetak Island Setting
R. Thomas Bell, David Hickman, Lance Yamaguchi, William Jackson, and Terry Hamilton
This article was submitted to Health Physics
January 2002
DISCLAIMER This document was prepared as an account of work sponsored by an agency of the United States Government. Neither the United States Government nor the University of California nor any of their employees, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, or service by trade name, trademark, manufacturer, or otherwise, does not necessarily constitute or imply its endorsement, recommendation, or favoring by the United States Government or the University of California. The views and opinions of authors expressed herein do not necessarily state or reflect those of the United States Government or the University of California, and shall not be used for advertising or product endorsement purposes. This is a preprint of a paper intended for publication in a journal or proceedings. Since changes may be made before publication, this preprint is made available with the understanding that it will not be cited or reproduced without the permission of the author.
__________________________________Paper_________________________________ A Whole Body Counting Facility in a Remote Enewetak Island Setting
R. Thomas Bell*, David Hickman§, Lance Yamaguchi¤, William Jackson*, Terry Hamilton§
Abstract - The U.S. Department of Energy (DOE) has recently implemented a series of strategic
initiatives to address long-term radiological surveillance needs at former US test sites in the Marshall
Islands. The plan is to engage local atoll communities in developing shared responsibilities for
implementing radiation protection programs for resettled and resettling populations. As part of this
new initiative, DOE agreed to design and construct a radiological laboratory on Enewetak Island,
and help develop the necessary local resources to maintain and operate the facility. This cooperative
effort was formalized in August 2000 between the DOE, the Republic of the Marshall Islands (RMI),
and the Enewetak/Ujelang Local Atoll Government (EULGOV). The laboratory facility was
completed in May 2001. The laboratory incorporates both a permanent whole body counting (WBC)
system to assess internal exposures to 137Cs, and clean living space for people providing 24-h void
urine samples. DOE continues to provide on-going technical assistance, training, and data quality
review while EULGOV provides manpower and infrastructure development to sustain facility
operations on a full-time basis. This paper will detail the special construction, transportation and
installation issues in establishing a whole body counting facility in an isolated, harsh environmental
setting.
Key Words: Marshall Islands, Enewetak Radiological Facility, WBC, 137Cs * U.S. Department of Energy, Office of Health Studies, EH-6/270CC, Germantown MD 20874-1290 § Health and Ecological Assessment Division, L-286, Lawrence Livermore National Laboratory, Livermore CA 94551-9900 ¤ Bechtel Nevada, P.O. Box 29939, Honolulu, HI 96820-2339
Introduction Enewetak Atoll is located in the remote northwestern corner of the Marshall Islands,
some 2700 miles west of Hawaii (Fig.1).
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Immediately after WWII, the United States created a Joint Task Force to develop a
nuclear weapons testing program. Planners examined a number of possible locations in
the Atlantic, the Caribbean, and the Pacific but decided that coral atolls in the northern
Marshall Islands offered the best advantages of stable weather conditions, fewest
inhabitants to relocate, and isolation with hundreds of miles open ocean to the west where
trade winds were likely to disperse radioactive fallout. After an initial series of tests on
Bikini Atoll in 1946, local inhabitants of Enewetak were moved to a new home on
Ujelang Atoll in December 1947 in preparation for the scheduling of the first nuclear test
on Enewetak in 1948 (Micronesian Support Committee). By the time the test moratorium
came into effect in 1958, the United States had conducted a total of 43 tests on Enewetak
Atoll. The atoll continued to be used for defense programs until the start of a cleanup and
rehabilitation program in 1977. The people of Enewetak remained on Ujelang Atoll until
resettlement of Enewetak Island in 1980. Since 1972, the Department of Energy has
conducted a number of scientific missions to Enewetak and published a number of
reports on radiation exposure in the Enewetak population. (Robison et al. 1973; Robison
et al. 1980; Robison et al. 1987; Robison et al. 1998, Sun et al. 1997). The permanent
resident population of Enewetak Atoll now total over 800 with most people living on
Enewetak Island in the south where residual levels of fallout contamination are very low.
Dose estimates based on environmental data as well as periodic WBC monitoring data
supplied by the Brookhaven National Laboratory indicate internal radiation doses from
fallout radionuclides (mostly 137Cs) are decreasing with time, and that the present day
effective dose rates are well below what could be reasonably considered harmful to
human health (Sun et. al., 1997). Despite of these assurances, the local community has
3
developed a societal fear of radiation, and has consistently expressed concerns about the
increased risk of radiation exposure living on the island. There has also been lasting
concerns about the radiological safety of using the northern reaches of the lagoon for
food gathering and fishing. In August, 2000, the DOE responded with a new initiative.
A Memorandum of Understanding (MOU) was developed in cooperation with the
Enewetak/Ujelang Local Atoll Government (EULGOV) and the Republic of the Marshall
Islands. The DOE agreed to provide funding for a dedicated facility on Enewetak Island
to house a permanent whole body counter, contribute to the salaries to pay local
technicians to operate the facility, and analyze a representative number of urine samples
for plutonium using advanced accelerator mass spectrometric technologies available at
LLNL.
Special Facility Construction
The selection of a building type that could withstand high exterior temperatures and yet
be able to maintain a constant air-conditioned interior was a particular challenge.
Fortunately, the United States Army Kwajalein Atoll Command (USAKA) had just
begun installation of new officer living quarters utilizing an igloo type fiberglass double
wall insulated structure that met these specifications. This type of structure is also
contoured to help reduce damage from high winds in the case of a typhoon. Thus, the
“Kwajalein igloo’ served as the prototype for the pre-fabricated building purchased for
Enewetak Atoll. All the materials for the building had to be purchased in the United
States and shipped to Kwajalein in two (2) 40 ft. containers. A vessel, contracted locally
in the Marshall Islands, delivered the unassembled structure, equipment, and construction
materials to Enewetak in October 2000.
4
A building site was chosen at the far northern end of island in a low background
environment but in reasonable proximity to existing infrastructure (e.g., electrical
generators and reverse osmosis water plant). At the same time, some attention was given
to siting the building away from obvious sources of natural background radiation such as
fuel storage tanks. Transporting all the building materials to this remote island location
about 300 km from Kwajalein resulted in a logistics cost of about $137,000.
During construction, each modular shell section had to be secured to the adjoining section
with hundreds of bolts. A concrete foundation laid down inside the building to support
the weight of the whole body counter also provided additional anchor support for
individual sections dovetailing into the concrete. Special internal scaffolding, provided
by the manufacturer for this type of structure, was used and proved invaluable in the
initial stages of assembly. The structural shell was assembled within a 4-week period
during December 2000 (Fig. 2).
An additional $130,000 was required to complete the interior design of the building,
purchase appliances and provide amenities; $50,000 for all the WBC detectors,
associated electronics and computers; and a planned expenditure of $18,000 for purchase
and installation of a satellite communication system. Electrical power and water are
supplied through the local Enewetak Field Station. However, DOE agreed to augment
existing electrical generator capacity on Enewetak Island with a new 125-kilowatt unit to
help ensure a sufficient supply of electricity to meet the full and continuous requirements
5
of the facility. DOE will slowly recuperate costs of the generator as power and water are
supplied on a reimbursable rate. The full laboratory facility includes a bathroom and
shower, washer and dryer, a fully equipped kitchen, laboratory space with fume hood,
and sleeping quarters to accommodate for up to 8 people during an overnight stay to
collect urine samples in a clean, contamination-free environment.
The total cost of the whole facility including the whole body counting equipment was
approximately $335,000. This included all the transportation costs of shipping
equipment, building materials and supplies to Enewetak. The building was formally
opened at a dedication service held on May 9, 2001 (Fig. 3) and has been fully
operational as a WBC facility since May 29, 2001.
Whole Body Counter
The Whole Body Counter (WBC) installed on Enewetak Island is designed to be operated
with a Sodium Iodide (NaI) detector that will detect small quantities of high-energy
gamma emitting radionuclides. The NaI detector is a 28 cm diameter 10 cm thick solid
crystal and is very delicate. The NaI is housed inside a 4.8-cm thick shield that can be
rotated to allow for the maximum observation of the entire body. A Canberra Inspector
and associated whole body counting software specifically designed for the NaI detector is
interfaced to a desktop computer.
The whole body counter includes a lead core shadow shielded chair that was refurbished
and transported to Enewetak Island on a small boat. The patient sits inside the shadow-
6
shielded enclosure on a chair that can be adjusted back and forth to assure the proper
counting distance. This design of whole body counter is typically referred to as a Masse-
Bolton Chair design (Masse and Bolton, 1970). The Masse-Bolton Chair design is
sufficient to monitor for radionuclides in most of the body and all of the internal organs.
The back of the chair can be adjusted to be 350 to 500 cm from the detector. The
positioning of the patient will nominally achieve a 300 to 350 cm arch along the midline
of the sitting patient. Positioning the patient (i.e., distance of the midline of the patient to
the detector) is important if accurate and repeatable results are to be obtained. Calibration
of the system is performed using a Bottle Man-akin Absorption (BOMAB) phantom
filled with a known amount of mixed gamma emitting radionuclides (Fig.4.)
The final assembly, calibration and operational readiness of the whole body counting
system were completed by LLNL scientists during an on-site visit in late May, 2001.
Immediately prior to the scientific mission, two local WBC technicians received six
weeks of specialized training at the LLNL focusing on basic radiological worker training
and whole body counting. All aspects of the routine WBC monitoring program are
controlled by the local technicians using documented procedures. However, LLNL
scientists continue to play an integral part in the process by providing advanced training
for technicians, helping with systems maintenance and trouble shooting, and data quality
assurance. Advanced plans have been made of DOE, in conjunction with the Republic
of the Marshall Island’s National Telecommunication Authority, to purchase and install a
state-of-the-art satellite communication system at the Enewetak laboratory, to support
scientific work. The system will have phone, fax and data-transfer capabilities that,
7
among other things, will enable technicians and LLNL personnel to perform real-time
diagnostics on the computer equipment and improve quality controls.
Quality Assurance Measures and Data Management Local Marshallese whole body counting technicians are responsible for all daily
operations in the WBC facility while scientists from the Lawrence Livermore National
Laboratory (LLNL) provide on-going technical assistance, training, and quality review.
Each volunteer receives a preliminary written report (in Marshallese and/or English as
needed) from the WBC technician immediately after counting. The preliminary report
shows the total amount of 137Cs and naturally occurring 40K detected, and gives an
estimated annual dose based on a chronic intake.
The WBC electronic database files are backed up on transportable disc media, and
forwarded to LLNL with hardcopy documentation for quality assurance review (Fig. 5).
The daily background counts, standard source checks, and personal counts are loaded into
a mirror computer system at LLNL. The information is carefully reviewed by program
personnel to assure compliance with control limits and validate database information with
paper records. Count results are checked against established data quality assurance
objectives to assure that results are reasonable relative to other known environmental
levels and historical measurements obtained from the Marshall Islands program. The
accepted data are exported into an ASCII comma delimited file, the data import is
verified and sorted, and a secondary level of quality assurance performed on the data
8
before its placed into a permanent Access 2000 (MS Project) database. At the same time,
the original and a copy of WBC report are stamped as having passed QA–the final
stamped copy of the report is returned to the individuals concerned using the postal
service. The non-accepted data are moved into an unresolved listing for further review.
Attempts are made to resolve outstanding quality assurance issues by satellite
communication, radio-patch and/or distribution of written procedures to the WBC
technicians in the field. Any data that is resolved enters back into the data quality
assurance stream otherwise the count is rejected. Updates to the Access 2000 database
are forwarded to DOE on a quarterly basis, and the information made publicly available
on the World Wide Web. A summary of individual whole body counting results and their
relationship to the minimum detectable level of ~ 0.06 kBq is provided in (Fig. 6).
Conclusions
The completion by DOE of the Enewetak Radiological Facility on Enewetak Island in the
Marshall Islands represents a unique logistic undertaking. Transportation of the specially
designed structure to such a remote setting and its fabrication was a real challenge.
Equipping the facility with modern state-of-the-art whole body counting detectors,
equipment, computers, and satellite communication capabilities represented a carefully
planned and executed process. Equipment installed had to be able to operate under harsh
environmental conditions and be operable by trained local Enewetak community
technicians. This effort was a collective effort that involved DOE planning, LLNL
supervision and oversight, superior efforts of the DOE logistical contractor (Bechtel
Nevada) including transportation, facility assembly, completion of the interior and
support amenities, and the cooperation and help of the Enewetak community. The lessons
9
learned from this project can be of use to others who are considering how to set up
distantly operated technical facilities, in other remote world settings. Installation of a
reliable consistent supply of electrical power for the whole body counting and computer
support equipment, HEPA-filtered air-conditioning and general facility operation was of
paramount importance to the successful implementation of a whole body counting
capability on Enewetak Island on a year-around basis. A source of fresh water required
the installation of a reverse osmosis (R/O) unit to process nearby seawater. The
Enewetak community is proud of its new radiological facility and the meaningful
involvement of its own, trained citizens. The community sense of pride helps with the
continued operation and maintenance of the facility and facilitates improved
communications and cooperation with DOE counterparts. The monitoring capability it
provides for local Enewetak inhabitants provides assurance that environmental doses
from ingestion of 137Cs and naturally occurring 40K in locally grown foods remains at low
levels that impose no health risk.
Acknowledgment This work was performed under the auspices of the U. S. Department of Energy by the University of California, Lawrence Livermore National Laboratory under Contract No. W-7405-Eng-48. References Masse, F. X.; Bolton, M. M. Jr.
Experience with a low-cost chair-type detector system for determination of radioactive body burdens of M.I.T. radiation workers. Health Phys. 19(1): 27-35, 1970.
Micronesian Support Committee, Marshall Islands, A Chronology: 1944-1981)
Washington DC Library UF 890.M35 C. Robison, W. L. Dose estimates for the marine food chain. In: Enewetak radiological
survey. Las Vegas; U.S. Atomic Energy Commission, Nevada Operations Office; NVO-140, Vol. 1; 1973: 526-541.
10
Robison, W. L.; Phillips, W. A, Mount, M. E.; Clegg, B. R.; Conrado, C. L. Reassessment of the potential radiological doses for residents resettling Enewetak Atoll, Lawrence Livermore National Laboratory, UCRL-53066, 1980.
Robison, W. L.; Conrado, C. L.; Phillips, W. A. Engebi Island Dose Assessment.
Livermore, CA. Lawrence Livermore National Laboratory; URCL-53805; 1987. Robison, W. L.; Noshkin, V. E. Radionuclide characterization and associated dose from
long-lived radionuclides in close-in fallout delivered to the marine environment at Bikini and Enewetak Atolls. Livermore CA. Lawrence Livermore National Laboratory; UCRL-JC-130230; 1998.
Sun, L. C.; Clinton, J. H.; Kaplan, E. Meinhold, C.B. 137Cs exposure in the Marshallese
populations: An assessment based on whole-body counting measurements (1989 – 1994). Health Phys. 73(1): 86-99: 1997.
Sun, L. C.; Meinhold, C. B.; Moorthy, A. R.; Kaplan, E., and Baum, J. W. Assessment of
plutonium exposure in the Enewetak population by urinalysis. Health Phys. 73(1): 127-132; 1997.
Figure 1. Map of the Marshall Islands atolls showing Enewetak Atoll at the upper left.
Map File “NETSCAjpg~1.jpg” Figure 2. Construction of the modular shell sections utilizing internal scaffolding.
File: “dcp00433.jpg” Figure 3. The newly constructed radiological facility on Enewetak Island – this “igloo design is a low maintenance facility ideally suited to withstanding high wind and harsh sea salt environments.
File: “sideview.jpg” Figure 4. Bottle Man-akin Absorption (BOMAB) calibration phantom seated in a whole body counting chair.
File: “WBC Chair with Calibrator.jpg” Figure 5. Schematic outline of the WBC Quality Assurance Plan (WAP).
File: “WBC_flowchartcopy.jpg Figure 6. Whole body burdens detected (kBq) in the resident population using locally operated WBC technicians.
File: “Enewetak rad lab wbc copy.jpg”
Figure 1. Map of the Marshall Islands atolls showing Enewetak Atoll at the upper left.
Figure 2. Construction of the modular shell sections utilizing internal scaffolding.
Figure 3. The newly constructed radiological facility on Enewetak Island—this “igloo” design is a low maintenance facility ideally suited to withstanding high wind and harsh sea salt environments.
Figure 4. Bottle Man-akin Absorption (BOMAB) calibration phantom seated in a whole body counting chair.
Figure 5. Schematic outline of the WBC Quality Assurance Plan (WAP).
Figure 6. Whole body burdens detected (kBq) in the resident population using locally operated WBC technicians.